Dissolved phosphorous through dry-wet-dry transitions in a small-dammed river basin: integrated understanding on transport patterns, export controls, and fate

An integrated understanding of dissolved phosphorous (DP) export mechanism and controls on export over dry and wet periods is crucial for riverine ecological restorations in dammed river basins considering its high bioavailability and retention rates at dams. Riverine DP transport patterns (composit...

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Bibliographic Details
Published in:Environmental science--processes & impacts 2025-01, Vol.27 (2), p.373-389
Main Authors: Mihiranga, H K M, Jiang, Yan, Sathsarani, M G S, Li, Xuyong
Format: Article
Language:English
Subjects:
Agricultural land
Agricultural wastes
Base flow
Bioavailability
Coefficient of variation
Creeks & streams
Dams
Dry season
Export controls
Fluxes
Groundwater
Groundwater runoff
Groundwater treatment
Heterogeneity
Human influences
Moisture content
Rainy season
River basins
Rivers
Runoff
Seasons
Soil water
Soil water storage
Solid suspensions
Surface runoff
Total suspended solids
Traditional farming
Trends
Wastewater treatment
Wastewater treatment plants
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Summary:An integrated understanding of dissolved phosphorous (DP) export mechanism and controls on export over dry and wet periods is crucial for riverine ecological restorations in dammed river basins considering its high bioavailability and retention rates at dams. Riverine DP transport patterns (composition, sources, and transport pathways), export controls, and fate were investigated over the 2020 wet season (5 events) and dry seasons before and after it (2 events: dry and dry ) in a semi-arid, small-dammed watershed to comprehend the links between terrestrial DP sources and aquatic DP sinks. Close spatiotemporal monitoring of the full range of phosphorous and total suspended solids (TSSs) and subsequent analyses (hysteresis, hierarchical partitioning, and coefficient of variation) provided the basis for the study. Total-DP (TDP) shared 13-39% (25%) of total-P (TP) through storms, dissolved organic-P (DOP) shared 6-21% (12%), and phosphate-P shared (PO -P) 7-22% (13%). DP forms displayed strong connections with discharge trends across the wet season, and marked changes in the shares were reported over dry-wet and wet-dry transitions. The DOP fraction of TDP increased from 4% in dry baseflow to 64% at the end of the wet season. The DOP flux increment in stormflow was 20 folds compared to dry baseflow, while that of PO -P was 2 folds. DOP displayed the least spatial source heterogeneity with minimum anthropogenic pressure on inherent fluxes. DOP originated from overland and near-stream soil sources and was transported surface runoff and soil water runoff, respectively. Across the wet season, the attrition of overland DOP sources and activation of near-stream soil DOP sources through strengthened hydrological connectivity governed the seasonal DOP trends. Surface and groundwater runoff pathways were important for PO -P delivery during stormflow; nonetheless, wastewater treatment plant (WWTP) effluent was the main PO -P source under both baseflow and stormflow regimes, followed by near-stream traditional agriculture lands. The interaction patterns of small dam systems with DP inputs through dry-wet periods were explained. The riverine PO -P fluxes were profoundly impacted by in-stream biogeochemical and physical processes and small dam systems, while riverine DOP fluxes were relatively less influenced.
ISSN:2050-7887
2050-7895
2050-7895
DOI:10.1039/d4em00686k